Project description:Regulatory T (Treg) cells play an indispensable role in immune homeostasis. The development and function of Tregs are dependent on transcriptional factor Foxp3, but how constant expression of Foxp3 is maintained in Tregs is not clear. Here we show that ablation of the conserved non-coding DNA sequence 2 (CNS2) at the Foxp3 locus in mice led to spontaneous lymphoproliferative disease and exacerbation of experimental autoimmune encephalomyelitis (EAE). CNS2 is required for activated Treg cells to maintain elevated Foxp3 expression, which is critical for their suppressor function and lineage stability. Mechanistically, upon TCR stimulation, NFAT binds to both CNS2 and Foxp3 promoter and mediates the interaction between CNS2 and Foxp3 promoter. Our findings demonstrated an essential role for CNS2 in maintaining the stability and function of activated Treg cells and identified NFAT as a key mediator of its function. Gene expression was profiled in T regulatory cells (Treg) in WT and CNS2 knockout mice. CNS2 knockout mice lack a conserved non-coding DNA sequence 2 (CNS2) at the Foxp3 locus. Treg cells were further sorted into Foxp3-high and Foxp3-low populations based on the expression level of Foxp3. mRNA was profiled using RNA-Seq (unstranded, polyA+, SE100) in replicate for each condition

Project description:Regulatory T (Treg) cells play an indispensable role in immune homeostasis. The development and function of Tregs are dependent on transcriptional factor Foxp3, but how constant expression of Foxp3 is maintained in Tregs is not clear. Here we show that ablation of the conserved non-coding DNA sequence 2 (CNS2) at the Foxp3 locus in mice led to spontaneous lymphoproliferative disease and exacerbation of experimental autoimmune encephalomyelitis (EAE). CNS2 is required for activated Treg cells to maintain elevated Foxp3 expression, which is critical for their suppressor function and lineage stability. Mechanistically, upon TCR stimulation, NFAT binds to both CNS2 and Foxp3 promoter and mediates the interaction between CNS2 and Foxp3 promoter. Our findings demonstrated an essential role for CNS2 in maintaining the stability and function of activated Treg cells and identified NFAT as a key mediator of its function.

Project description:We investigated the role of DNMT1 in immune homeostasis by generating mice lacking DNMT1 in Foxp3+ T-regulatory (Treg) cells. These mice showed decreased peripheral Foxp3+ Tregs, complete loss of Foxp3+ Treg suppressive functions in vitro and in vivo, and died from autoimmunity by 3-4 weeks unless they received perinatal transfer of wild-type Tregs that prolonged their survival. Methylation of CpG-sites in the TSDR region of Foxp3 was unaffected by DNMT1 deletion, but microarray revealed more >500 proinflammatory and other genes were upregulated in DNMT1-/- Tregs. CD4-Cre-mediated DNMT1 deletion showed inability of conventional T cells to convert to Foxp3+ Treg under appropriate polarizing conditions. Hence, DNMT1 is absolutely necessary for maintenance of the gene program required for normal Treg development and function. RNA from three independent samples of magnetically separated CD4+CD25+ Treg of fl-DNMT1/Foxp3cre mice, compared to wild type (C57BL6) control

Project description:T-regulatory (Treg) cells are important to immune homeostasis, and Treg cell deficiency or dysfunction leads to autoimmune disease. An histone/protein acetyltransferase (HAT), p300, was recently found important for Treg function and stability, but further insights into the mechanisms by which p300 or other HATs affect Treg biology are needed. Here we show that CBP, a p300 paralog, is also important in controlling Treg function and stability. Thus, while mice with Treg-specific deletion of CBP or p300 developed minimal autoimmune disease, the combined deletion of CBP and p300 led to fatal autoimmunity by 3-4 weeks of age. The effects of CBP and p300 deletion on Treg development are dose-dependent, and involve multiple mechanisms. CBP and p300 cooperate with several key Treg transcription factors that act on the Foxp3 promoter to promote Foxp3 production. CBP and p300 also act on the Foxp3 CNS2 region to maintain Treg stability in inflammatory environments by regulating pCREB function and GATA3 expression, respectively. Lastly, CBP and p300 regulate the epigenetic status and function of Foxp3. Our findings provide insights into how HATs orchestrate multiple aspects of Treg development and function, and identify overlapping but also discrete activities for p300 and CBP in control of Treg cells. RNA from three independent samples from magnetically separated CD4+CD25+ Treg of fl-p300/Foxp3cre mice and fl-CBP/Foxp3cre, compared to wild type (Foxp3cre) control (all C57Bl/6 background).

Project description:We investigated the role of DNMT1 in immune homeostasis by generating mice lacking DNMT1 in Foxp3+ T-regulatory (Treg) cells. These mice showed decreased peripheral Foxp3+ Tregs, complete loss of Foxp3+ Treg suppressive functions in vitro and in vivo, and died from autoimmunity by 3-4 weeks unless they received perinatal transfer of wild-type Tregs that prolonged their survival. Methylation of CpG-sites in the TSDR region of Foxp3 was unaffected by DNMT1 deletion, but microarray revealed more >500 proinflammatory and other genes were upregulated in DNMT1-/- Tregs. CD4-Cre-mediated DNMT1 deletion showed inability of conventional T cells to convert to Foxp3+ Treg under appropriate polarizing conditions. Hence, DNMT1 is absolutely necessary for maintenance of the gene program required for normal Treg development and function.

Project description:Analysis of Foxp3(+)epigenetics(-) T cells, Foxp3(-)epigenetics(+) T cells, and Foxp3(+)epigenetics(+) T cells. Results indicate regulatory T cell (Treg) ontogenesis requires two independent processes, expression of the transcription factor Foxp3 and establishment of Treg epigenetic programs induced by T cell receptor (TCR) stimulation. GFP+CD4+ and GFP-CD4+ splenocytes were sorted from DEREG and DEREG/Scurfy mice. These cells were activated with anti-CD3/CD28 antibodies, and then transduced with Foxp3-expressing retrovirus (pGCSamIN, NGFR marker). NGFR+ T cells sorted were subjected to microarray analysis (Affymetrix, mouse genome 430 2.0 array). To normalize the experimental conditions, Tregs (GFP+ T cells from DEREG) and Tconv (GFP- T cells from DEREG) were also activated and transduced with empty vector. Two replicates each.

Project description:TET enzymes are essential for the stability and function of regulatory T cells (Tregs), which maintain immune homeostasis and self-tolerance and express the lineage-determining transcription factor Foxp3. We previously showed that Vitamin C acts through TET enzymes to maintain the demethylated status of CNS2, a key intronic enhancer of the Foxp3 gene that is essential for the stability of Foxp3 expression both in vivo and in vitro. Here we show that Vitamin C enables genome-wide features of “induced” T regulatory cells (iTregs) in vitro that overlap with those induced by TET proteins during Treg differentiation in vivo. Vitamin C enhances IL-2 responsiveness in iTregs by increasing phospho-STAT5 levels, STAT5 occupancy and DNA demethylation at key Treg-specific enhancers, and maintains the stable expression of Treg-specific genes including Foxp3 and Il2ra. Our data will be relevant to future studies of the association between plasma Vitamin C levels, Treg function and autoimmunity in humans.

Project description:TET enzymes are essential for the stability and function of regulatory T cells (Tregs), which maintain immune homeostasis and self-tolerance and express the lineage-determining transcription factor Foxp3. We previously showed that Vitamin C acts through TET enzymes to maintain the demethylated status of CNS2, a key intronic enhancer of the Foxp3 gene that is essential for the stability of Foxp3 expression both in vivo and in vitro. Here we show that Vitamin C enables genome-wide features of “induced” T regulatory cells (iTregs) in vitro that overlap with those induced by TET proteins during Treg differentiation in vivo. Vitamin C enhances IL-2 responsiveness in iTregs by increasing phospho-STAT5 levels, STAT5 occupancy and DNA demethylation at key Treg-specific enhancers, and maintains the stable expression of Treg-specific genes including Foxp3 and Il2ra. Our data will be relevant to future studies of the association between plasma Vitamin C levels, Treg function and autoimmunity in humans.

Project description:TET enzymes are essential for the stability and function of regulatory T cells (Tregs), which maintain immune homeostasis and self-tolerance and express the lineage-determining transcription factor Foxp3. We previously showed that Vitamin C acts through TET enzymes to maintain the demethylated status of CNS2, a key intronic enhancer of the Foxp3 gene that is essential for the stability of Foxp3 expression both in vivo and in vitro. Here we show that Vitamin C enables genome-wide features of “induced” T regulatory cells (iTregs) in vitro that overlap with those induced by TET proteins during Treg differentiation in vivo. Vitamin C enhances IL-2 responsiveness in iTregs by increasing phospho-STAT5 levels, STAT5 occupancy and DNA demethylation at key Treg-specific enhancers, and maintains the stable expression of Treg-specific genes including Foxp3 and Il2ra. Our data will be relevant to future studies of the association between plasma Vitamin C levels, Treg function and autoimmunity in humans.

Project description:TET enzymes are essential for the stability and function of regulatory T cells (Tregs), which maintain immune homeostasis and self-tolerance and express the lineage-determining transcription factor Foxp3. We previously showed that Vitamin C acts through TET enzymes to maintain the demethylated status of CNS2, a key intronic enhancer of the Foxp3 gene that is essential for the stability of Foxp3 expression both in vivo and in vitro. Here we show that Vitamin C enables genome-wide features of “induced” T regulatory cells (iTregs) in vitro that overlap with those induced by TET proteins during Treg differentiation in vivo. Vitamin C enhances IL-2 responsiveness in iTregs by increasing phospho-STAT5 levels, STAT5 occupancy and DNA demethylation at key Treg-specific enhancers, and maintains the stable expression of Treg-specific genes including Foxp3 and Il2ra. Our data will be relevant to future studies of the association between plasma Vitamin C levels, Treg function and autoimmunity in humans.